Phototubes for scintillation detector

ABSTRACT

The invention relates to phototubes and in particular to photo multiplier tubes such as those associated with scintillation crystals and which are provided with an array of conductor elements juxtaposed with respect to the photo cathode of the tube and which when subjected to voltage pulsing in a scanning sequence are capable of providing information concerning the spatial distribution of light incident on the photo cathode.

United States Patent Suhami et al.

[54] PHOTOTUBES FOR SCINTILLAT ION DETECTOR e [72] inventors; Albert Suhami; Benjamin Sabbah;

Dan Inbar, all of Haifa; Artzi' Yarom, Jerusalem; Dan Ben-Zeev,

' Haifa, all of Israel [73] Assignee: Elsclnt Ltd., Haifa, Israel [22] Filed: Jan. 7, 1970 211 Appl. No; 1,198

[52] US. Cl. ........250/7 1.5 R, 313/102 [51] Int. Cl....... ..G01t 1/20 [58] Field of Search ..313/102;250/7l.5

[56] References Cited UNITED STATES PATENTS 2,512,146 6/1950 Fulmer ..313/1'02 x [151 3,701,901 [4 "Oct. 31, 1972 2,772,368 11/1956 Scherbatskoy ..250/71.5 X 2,818,520 12/1957 Engstrom et a1.......3l3/102 X 2,829,264 4/ 1958 Garrison ..250/71.5 3,011,057 11/1961 Anger ..250/71 .5 3,026,412 3/ 1962 Carlson ..250/71.5

Primary Examiner-Archie R. Borchelt Attorney-Browdy and Neimark [57] ABSTRACT I The invention relates to phototubes and in particular to photo multiplier tubes such as those associated with scintillation crystals and which are provided with an array of conductor elements juxtaposed with respect to the photo cathode of the tube and which when subjected to voltage pulsing in a scanning sequence are capable of providing information concerning the spatial distribution of light incident on the photo cathode.

13 Claims, 7 Drawing Figures oopoo,oooo

PATENTEMBTBHSR 3.701.901

- ,mtnanrs II IIIIIIIIIIII IIIIIIIIIIII III-I III. III. IIIIIIIIIIII IIIIIIIIIIII IIIIIIIIIIII IIIIIIIIIIII IIIIIIIIIIII NVENTQQ PHOTOTUBES FOR SCINTILLATION DETECTOR This invention relates to photo tubes and in particular to photo multiplier tubes such as photo multiplier tubes associated with scintillation crystals. Photo tubes act as light detectors and convert a light input, incident on a photo cathode into an electrical output. This electrical output is a function of the light intensity incident on the photo cathode and is independent of the spatial distribution of the light on the cathode. Where information is required concerning this spatial distribution, involved and elaborate steps have to be adopted in order to secure such information.

Thus, for example, a photo multiplier is used in conjunction with a scintillator crystal to form a scintillator counter capable of detecting radiation such as gamma or X-rays- Whenever, a gamma ray, for example, is absorbed by the scintillator crystal a current pulse is derived from the photo multiplier having an intensity corresponding to the energy of the ray absorbed and having a decay time which is characteristic-of the scintillator. No information is, however, obtained as to the precise position at which the gamma ray impinged on and interacted with the scintillator. Where it is desired to obtain information concerning the spatial distribution of the impinging radiation the region must either be scanned by the counter or a multi-counter arrangement must be used so as to derive the information simultaneously. It will be readily appreciated that whereas the first of these alternatives is very time consuming the second alternative involves the provision of relatively elaborate equipment.

On the other hand in the use of a photo multiplier tube as a television camera the object to be televised is imaged on the photo cathode and raster scanning by an electron beam is employed in order to obtain information concerning the spatial distribution of the photo electrons emitted from the photo cathode. Such an arrangement also involves the use of complicated equipment.

It is the object of the present invention to provide a photo tube assembly which is capable of use in obtaining information concerning the spatial distribution of light radiation incident on a photo cathode.

According to the present invention there is provided a photo tube assembly comprising in combination a photo tube and an array of conductive elements juxtaposed with respect to the photo cathode of the photo tube.

It is widely known, from the literature that external electrostatic and/r electromagnetic fields may divert photoelectrons from their original path thus reducing the output current of a photomultiplier.

The present invention makes use of this known phenomenon in that the photo cathode is associated with an entire array of conductive elements to which voltage pulses can be selectively applied. After the occurrence of a light event (which can be detected by the use of a current pulse emitted from the photo tube) the entire surface of the photo cathode can be effectively scanned by applying voltage pulses to the constituent elements of the array in accordance with an appropriate sequence. In this way the particular conductive element closest to the location of the light event can be identified, seeing that as a result of the application of voltage pulse to this particular element a maximum interference with the emitted current pulse can be observed.

Preferably, the assembly forms part of a scintillation counter in which case the photo tube which is, in fact, a photomultiplier tube is associated with a scintillator crystal, means being provided forensuring that, as far as possible, any particular light event whose spatial location is to be identified as effectively isolated from any other simultaneously occurring light event thereby ensuring that the current pulse emitted by the photo multiplier is associated with only a single light event.

Preferably the photo tube assembly is formed as a single integral unit with the array of conductive elements embedded in the optical front end window of the photo multiplier directly adjacent the photo cathode.

In accordance with a preferred embodiment the constituent elements of the array are respectively constituted by the cross over regions of pairs of crossed, mutually insulated conductors which together form a lattice juxtaposed with respect to the photo cathode.

For a better understanding of the present invention and to show how the same can be carried out in practice reference will now be made to the accompanying drawings, in which:

FIG. 1 is a schematic representation of a scintillation counter incorporating a photo multiplier assembly in accordance with the present invention,

FIG. 2 is a schematic plan view of the photo multiplier assembly shown in FIG. 1,

FIGS. 30 and 3b are curves showing the variation of photo-multiplier current with'time with a photo multiplier assembly in accordance with the present invention in respect of a single light event and in connection with which scanning voltage pulses are applied respectively to adjoining wires of the matrix,

FIG. 4 is a partially cutaway perspective view of a front end window of a photo multiplier tube incorporating a photo cathode and a wire lattice in accordance with the present invention,

FIG. 5 is a cross sectional view of a portion of the window shown in FIG. 4, and

FlG. 6 is a schematic view of a modified form of an array of conductive elements forming part of a photo multiplier assembly in accordance with the invention.

As seen in FIG. 1 of the drawings a scintillator counter comprises a photo multiplier I having a front end window 2 on which is formed a photo cathode (not seen). A scintillator crystal 3 is located opposite the front end window 2 of the photo multiplier l and is separated therefrom by spacer supports 4, an air gap 5 being defined between opposite faces of the scintillator crystal 3 and the front end window 2. Located in this air gap 5 is a matrix 6 of m X m crossed, mutually insulated wires (m wires in the x direction and n wires in the y direction). Radiation 7 impinges on the scintillator crystal 3 each particular impinging radiation event giving rise to a corresponding light event 8. The presence of the air gap 5 between the scintillator crystal 3 and the end window 2 has as a consequence that only light rays originating in a light event 8 and located within a cone of aperture corresponding to the critical angle will traverse the air 'gap and strike the photo cathode of the photo multiplier. All the remaining light rays originating from that light event will be reflected at the surface of the scintillator crystal and upon impinging at the other surface thereof are absorbed on a light absorber layer 9. In this way it is ensured that, for any single light event 8"which corresponds to a single ray of impinging radiation only one localized cone of light will be formed and will be received by the photo cathode. Thus, if for example, the relevant critical angle is 40 and the thickness of the scintillator crystal is d then the diameter of the light cone striking the photo cathode will be of the order of 2d. Thus, with a crystal of one quarter inch in width, a half inch diameter light circle will be obtained on the photo cathode and this area (of the order of 2d) can be defined as being a resolution element or elemental area. It is a reasonable approximation to assume that with an assembly as schematically shown in FIG. 1, all rays which are simultaneously incident on a specified resolution element on a photo cathode originate in a specified light event located directly opposite that resolution element.

lf reference is now made to FIG. 2 of the drawings, we can see that the wire lattice is so arranged that the intersection of each pair of crossing wires can be considered to be associated with a specific resolution element of the photo cathode and that effectively the electric field which is developed as a result of the application of an electric voltage to this pair of crossing wires is sufficiently intense over this entire resolution element as to interfere with the normal path of photoelectrons emitted from this resolution element to the dynode.

Thus, if upon the occurrence of a light event and the incidence of the light thereby produced on a specific resolution element of the photo cathode the application of a positive voltage pulse of width t to one of the wires of the matrix located opposite the resolution element will have the result that the photo electrons emitted from that resolution element will be prevented from reaching the first dynode for a period of time t. FIG. 3a shows graphically a current pulse obtained from the photo multiplier of a scintillation counter as a result of the occurrence of a scintillation event with a decay time 1- when a voltage pulse of the width t (t r) is applied to one of the wires of the lattice located adjacent the resolution element of the photo cathode and directly opposite the location of the scintillation event. As can be seen, the application of the voltage pulse to this wire diverts the current for the period of time T so that a valley is produced in the representation of the photo multiplier output current pulse. When, as shown in FIG. 3b of the drawings the positive voltage pulse is applied to a wire adjacent a resolution element which neighbors but is not directly opposite the location of the scintillation event a valley will be produced which is of much lesser depth than the valley shown in FIG. 3b. Similarly, where the voltage pulse is applied to a wire still further removed from the location of the scintillation event no valley whatsoever will be observed.

It will become apparent therefore that in order to establish the precise location of a scintillation event the photo cathode must be scanned by the application of voltage pulses to all the wires of the lattice in an appropriate sequence so as to determine the identity of the pair of crossing wires whose intersection is located opposite the location of the scintillation event and which, when voltage pulses are applied thereto, cause the production of valleys of maximum depth in the photo multiplier current output pulse.

The particular scanning sequence which is adopted is dictated by the fact that scanning has to be completed well within the normal decay time of a scintillation event. With this end in view a so-called successive approximation scanning sequence is adopted. Scanning these elements by successive approximations involves starting with the entire area and dividing this area in two parts forevery scanning step.

Consider the provision of a lattice having 2" code grids in the x direction (i.e., 2" conductors spaced along the x direction) and 2 code grids in the y direction (i.e., 2 conductors spaced along the y direction). Thus p and q are respectively the powers to which 2 must be raised to obtain the number of conductors in the x and y directions respectively. Where, as in the example shown the lattice is made of 32 wires in the x direction and 32 wires in the y direction p and q are both equal to 5.

The pulsing sequence of the lattice will consist of p q pulses applied in steps m m, m Thus, if m, is the pulsing step number all the grids in the x direction from [(2 ""p) (n-l +1 to (2"""p)n where n 1,3,5

. (2"p 1) will be triggered at each step until m, p. 2

After that all the grids in the y direction will be triggered according to the same sequence from [(2""q) (n1)-l- 1 to (2""q)n where n 1,3,5 (2"'q l) at each step until m.,= q.

1n the particular example given p=q=5 and 2"=2"=32 for: m,,=l n=hll p wires from 1 to 16 will be triggered for: m,,=2 (n=1 l to 8 (n= 3 17 to 24 for: m,=3 (n=1 l to 4 (rt-=3 9 to 12 will be triggered (n=5 17 to 20 (n=7 25 to 28 for: m ,=4 (n=l 1 to 2 (n=3 5 to 6 (n=5 9 to 10 (n=7 13 to 14 will be triggered 17 to 18 (n=l1 21 to 22 (n=13 25 to 26 (n=15 29 to 30 for: m,,=5 n=l,3,5 31 all p wires l,3,5..... 31 will be triggered After the five p steps, the five q steps will trigger consecutively the q wires according to the same sequence.

The sequence of voltage pulse to be applied to the wires of the lattice is initiated by the rise time of a scintillation pulse reaching the anode of the photo multiplier. The transit time for photo electrons coming from the photo cathode and passing to the anode depends on the location of the point of origin of the photo electrons, this transit time being different for photo electrons coming from different parts of the photo cathode. In order to ensure that the sequence observations to be made are not influenced by these transit times it is arranged that initially a positive voltage pulse is applied to all the x wires of the lattice directly after the rise of a scintillation pulse is received by the anode of the photo multiplier. Seeing that a scintillation has occurred photo electrons are emitted by one of the resolution elements of the photo cathode and seeing that all the resolution elements are covered by the x wires the application of pulses to all the 1: wires must result in the appearance of a valley. The precise instant in time when this valley appears depends, of course, on the transit time of the photo electrons to the anode which, inits turn, is dependent, inter alia, on the location of the specific resolution element from which electrons are emitted. The appearance of this first valley will therefore serve as a time reference for all the subsequent valleys to be detected as a result of the application of subsequent scanning pulses in the successive approximation sequence; Thus, with the appearance of" the first valley the application of the subsequent crystal from the photo cathode with an air gap located between them. This arrangement is effective in the detection of relatively high energy incident radiation. In an alternative arrangement which is designed for use in the detection of relatively low energy radiation the single scintillator crystal is replaced by a matrix of scintillator crystals which are located on the end window of the photo multiplier with no air gap therebetween. The construction of the matrix of crystals ensures that only -a single scintillation effect can take place in'a single crystal and that the light emanating from the single crystal reaches only a single resolution element.

In accordance with a preferred embodiment the wire lattice is incorporated in the end window of the photo multiplier tube, the photo multiplier assembly in accordance with the invention being constructed as an in- .tegral whole. Such an arrangement is shown in FIGS. 4

and 5 of the accompanying drawings which show the construction of the photo multiplier and window. The

'window consists of outer and inner glass layers 11 and always obtained as aresultof applying pulses to all the x wires; Detection is effected by opening a linear gate l I layer 11, namely:

' a layer of crosswise conductive strips l3 formed of at given intervals and examining the pulse area with a discriminator. In order to ensure the highest possible sensitivity in detection, area discrimination is employed (not pulse height discrimination), seeing that such a technique enables adequate differentiation between real valleys and mere statistical fluctuations. Area discrimination technique involves the integration of the entire valley area and discrimination on the basis of total charge. In view of the fact that, as can be seen in FIGS. 3a and 3b of the drawings, the total current pulse height decreases with a time constant which cor-- responds to the decay constant of the scintillation event, in order to ensure that consecutive valleys should have the same absolute area, (so as to allow for the carrying out of area discrimination), the width of the successive pulse to be applied to the successive wires of the lattice must be varied. Discrimination will therefore always have to be triggered at the same level thus avoiding the different statistical considerations at different level. r

In order to carry out energy discrimination on the photo multiplier current pulse only those'portions of the pulse on either side of the valley can be considered. For this purpose the pulse is divided into three portions, namely, the front, the middle (the coded valley portion) and the tail. Only the front and tail portions are used for energy discrimination. In order to enhance the position determining action of the voltage pulses as applied to the lattice wires each lattice wire can be associated with a pair of adjacent wires which can be earthed or so biased as to enhance the appearance of valleys and shield from side interference.

It will be understood that, in order to ensure that the applied voltage pulses are effective in preventing or delaying the passage of photo electrons from the photo cathode to the dynode the wire lattice should be located as close as possible to the photo cathode.

In the specific embodiment of a scintillator counter described above the means adopted for ensuring that only the light originating in a single scintillation event reaches a specified resolution element of the photo cathode involves the spacing of the single scintillator 12. Deposited on the inner glass layer 12 is a photo cathode layer 13. Sandwiched between the glass layers 1-2 and 11 are to be found the following layers,

proceeding in order from the inner layer 12 to the outer metal mesh.

a glass layer 14.

a layer of lengthwise conductive strips 15 made of metal mesh.

a glass layer 16, and v a reflecting matrix 17 formed of a honeycomb metal structure.

In this embodiment the crosswise and lengthwise metal strips 13 and 15 constitute the conductive lattice in accordance with the invention whilst the reflecting matrix 17 is .provided in order to ensure that the light entering the end window does not diffuse through the window but is optically piped from one end of the window to the other.

Alternatively any other light piping arrangement can be employed such as, for example, critical angle piping.

In order to reduce, in an embodiment such as that just described with reference to FIGS. 4 and 5 of the drawings,'th e electrostatic shielding effect of the set of x wires (between the photocathode and the set of y wires) various alternative measures can be adopted. Thus, the x wires can be isolated from earth by electronicswitching during the period that pulsing of the y wires takes place.

In an alternative embodiment shown schematically in FIG. 6 the juxtaposed lattice of conductors is replaced by an array of conductive mesh elements 19 which is juxtaposed with respect to the photocathode in such a manner that each resolution element (as hereinbefore defined) of the photocathode is covered by a mesh element 19. Each mesh element is connected to a pair of x and y wires (possibly located externally to the voltage pulse sources via diodes 20 and 21 which prevent current flow between the x and y wires via the mesh elements 19. Each element 19 is coupled to earth via a resistance 22.

Whilst all the applications of the photo tube assembly in accordance with this invention specifically described above have been in connection with scintillator counters, it will be readily appreciated that such a tube and in particular photo multiplier assemblies, in accordance with the invention, can be adapted for other uses. Thus, a photo multiplier assembly, in accordance with the present invention can be used, for example, in a television camera wherein a picture can be optically projected onto the photo cathode and the conductive lattice can be employed to effect scanning of the photo cathode surface and thus to modulate the electric output of the camera. The picture can then be reconstructed from the modulated signal.

We claim:

1. An assembly comprising:

a. scintillator crystal means adapted to be excited by spatially distributed radiation events to produce correspondingly distributed light events that provide photoelectrons;

a phototube having a photocathode adapted to receive said photoelectrons; and

c. a plurality of electrically separate conductors arrayed in juxtaposition to said photocathode each of said conductors being associated with an elemental area of said photocathode so that the flow of current in a selected one of said conductors during the occurrence of a light event causes the resultant field to interfere with the flow of photoelectrons to the elemental area associated with said selected one of said conductors.

2. An assembly according to claim 1 wherein said array of conductors form a cross grid.

3. An assembly according to claim 1 wherein said conductors are interposed between said crystal means and said photocathode.

4. An assembly according to claim 1 wherein a gap exists between said crystal means and 'said photocathode.

5. An assembly according to claim 1 wherein said photocathode is included in an end window of said phototube, and said conductors are incorporated into said end window.

6. An assembly according to claim 1 wherein said crystal means is constituted by a matrix of separate component crystals.

7. An assembly comprising:

a. scintillator crystal means adapted to by excited by spatially distributed ratiation events to produce correspondingly distributed light events that provide photoelectrons;

. a phototube having a photocathode adapted to receive said photoelectrons;

c. a plurality of electrically separate conductors arrayed in juxtaposition to said photocathode each of said conductors being associated with an elemental area of said photocathode so that the flow of current in a selected one of said conductors during the occurrence of a light event causes the resultant field to interfere with the flow of photoelectrons to the elemental area associated with said selected one of said conductors;

d. said array of conductors forming a crossed grid and being interposed between said crystal means and said photocathode; and

e. said photocathode being included in an end window of said phototube, and said grid being incorporated into said window. 8. An assembly accordmg to claim 5 wherein said end window furthermore incorporates a light piping arrangement capable of optically piping light through said end window.

9. An assembly according to claim 1 wherein said conductors are constituted of strips of metallic mesh.

10. An assembly according to claim 9, wherein each conductor is adapted to be connected to a source of voltage pulses and is associated with juxtaposed conductors adapted to be oppositely biased with respect thereto.

11. An assembly according to claim 1 including an array of conductive regions juxtaposed with respect to the photo cathode, each region being arranged for coupling to a pair of said conductors via unidirectional current flow devices so as to prevent current flow between said pair of conductors via the regions.

12. An assembly according to claim 11, wherein said array is incorporated in an end window of said photo tube.

13. An assembly according to claim 12 wherein said end window furthermore incorporates a light piping arrangement capable of optically piping light through said end window. 

1. An assembly comprising: a. scintillator crystal means adapted to be excited by spatially distributed radiation events to produce correspondingly distributed light events that provide photoelectrons; b. a phototube having a photocathode adapted to receive said photoelectrons; and c. a plurality of electrically separate conductors arrayed in juxtaposition to said photocathode each of said conductors being associated with an elemental area of said photocathode so that the flow of current in a selected one of said conductors during the occurrence of a light event causes the resultant field to interfere wIth the flow of photoelectrons to the elemental area associated with said selected one of said conductors.
 2. An assembly according to claim 1 wherein said array of conductors form a cross grid.
 3. An assembly according to claim 1 wherein said conductors are interposed between said crystal means and said photocathode.
 4. An assembly according to claim 1 wherein a gap exists between said crystal means and said photocathode.
 5. An assembly according to claim 1 wherein said photocathode is included in an end window of said phototube, and said conductors are incorporated into said end window.
 6. An assembly according to claim 1 wherein said crystal means is constituted by a matrix of separate component crystals.
 7. An assembly comprising: a. scintillator crystal means adapted to by excited by spatially distributed ratiation events to produce correspondingly distributed light events that provide photoelectrons; b. a phototube having a photocathode adapted to receive said photoelectrons; c. a plurality of electrically separate conductors arrayed in juxtaposition to said photocathode each of said conductors being associated with an elemental area of said photocathode so that the flow of current in a selected one of said conductors during the occurrence of a light event causes the resultant field to interfere with the flow of photoelectrons to the elemental area associated with said selected one of said conductors; d. said array of conductors forming a crossed grid and being interposed between said crystal means and said photocathode; and e. said photocathode being included in an end window of said phototube, and said grid being incorporated into said window.
 8. An assembly according to claim 5 wherein said end window furthermore incorporates a light piping arrangement capable of optically piping light through said end window.
 9. An assembly according to claim 1 wherein said conductors are constituted of strips of metallic mesh.
 10. An assembly according to claim 9, wherein each conductor is adapted to be connected to a source of voltage pulses and is associated with juxtaposed conductors adapted to be oppositely biased with respect thereto.
 11. An assembly according to claim 1 including an array of conductive regions juxtaposed with respect to the photo cathode, each region being arranged for coupling to a pair of said conductors via unidirectional current flow devices so as to prevent current flow between said pair of conductors via the regions.
 12. An assembly according to claim 11, wherein said array is incorporated in an end window of said photo tube.
 13. An assembly according to claim 12 wherein said end window furthermore incorporates a light piping arrangement capable of optically piping light through said end window. 